""" TinyFlux-Deep with Expert Predictor Integrates a distillation pathway for SD1.5-flow timestep expertise. During training: learns to predict expert features from (timestep, CLIP). During inference: runs standalone, no expert needed. Based on TinyFlux-Deep: 15 double + 25 single blocks. """ import torch import torch.nn as nn import torch.nn.functional as F import math from dataclasses import dataclass from typing import Optional, Tuple, Dict @dataclass class TinyFluxDeepConfig: """Configuration for TinyFlux-Deep model.""" hidden_size: int = 512 num_attention_heads: int = 4 attention_head_dim: int = 128 in_channels: int = 16 patch_size: int = 1 joint_attention_dim: int = 768 pooled_projection_dim: int = 768 num_double_layers: int = 15 num_single_layers: int = 25 mlp_ratio: float = 4.0 axes_dims_rope: Tuple[int, int, int] = (16, 56, 56) # Expert predictor config use_expert_predictor: bool = True expert_dim: int = 1280 # SD1.5 mid-block dimension expert_hidden_dim: int = 512 expert_dropout: float = 0.1 # Dropout during training for robustness # Legacy guidance (disabled when using expert) guidance_embeds: bool = False def __post_init__(self): assert self.num_attention_heads * self.attention_head_dim == self.hidden_size assert sum(self.axes_dims_rope) == self.attention_head_dim # ============================================================================= # Normalization # ============================================================================= class RMSNorm(nn.Module): """Root Mean Square Layer Normalization.""" def __init__(self, dim: int, eps: float = 1e-6, elementwise_affine: bool = True): super().__init__() self.eps = eps self.elementwise_affine = elementwise_affine if elementwise_affine: self.weight = nn.Parameter(torch.ones(dim)) else: self.register_parameter('weight', None) def forward(self, x: torch.Tensor) -> torch.Tensor: norm = x.float().pow(2).mean(-1, keepdim=True).add(self.eps).rsqrt() out = (x * norm).type_as(x) if self.weight is not None: out = out * self.weight return out # ============================================================================= # RoPE - Old format with cached frequency buffers # ============================================================================= class EmbedND(nn.Module): """Original TinyFlux RoPE with cached frequency buffers.""" def __init__(self, theta: float = 10000.0, axes_dim: Tuple[int, int, int] = (16, 56, 56)): super().__init__() self.theta = theta self.axes_dim = axes_dim for i, dim in enumerate(axes_dim): freqs = 1.0 / (theta ** (torch.arange(0, dim, 2).float() / dim)) self.register_buffer(f'freqs_{i}', freqs, persistent=True) def forward(self, ids: torch.Tensor) -> torch.Tensor: device = ids.device n_axes = ids.shape[-1] emb_list = [] for i in range(n_axes): freqs = getattr(self, f'freqs_{i}').to(device) pos = ids[:, i].float() angles = pos.unsqueeze(-1) * freqs.unsqueeze(0) cos = angles.cos() sin = angles.sin() emb = torch.stack([cos, sin], dim=-1).flatten(-2) emb_list.append(emb) rope = torch.cat(emb_list, dim=-1) return rope.unsqueeze(1) def apply_rotary_emb_old(x: torch.Tensor, freqs_cis: torch.Tensor) -> torch.Tensor: """Apply rotary embeddings (old interleaved format).""" freqs = freqs_cis.squeeze(1) cos = freqs[:, 0::2].repeat_interleave(2, dim=-1) sin = freqs[:, 1::2].repeat_interleave(2, dim=-1) cos = cos[None, None, :, :].to(x.device) sin = sin[None, None, :, :].to(x.device) x_real, x_imag = x.reshape(*x.shape[:-1], -1, 2).unbind(-1) x_rotated = torch.stack([-x_imag, x_real], dim=-1).flatten(-2) return (x.float() * cos + x_rotated.float() * sin).to(x.dtype) # ============================================================================= # Embeddings # ============================================================================= class MLPEmbedder(nn.Module): """MLP for embedding scalars (timestep).""" def __init__(self, hidden_size: int): super().__init__() self.mlp = nn.Sequential( nn.Linear(256, hidden_size), nn.SiLU(), nn.Linear(hidden_size, hidden_size), ) def forward(self, x: torch.Tensor) -> torch.Tensor: half_dim = 128 emb = math.log(10000) / (half_dim - 1) emb = torch.exp(torch.arange(half_dim, device=x.device, dtype=x.dtype) * -emb) emb = x.unsqueeze(-1) * emb.unsqueeze(0) emb = torch.cat([emb.sin(), emb.cos()], dim=-1) return self.mlp(emb) # ============================================================================= # Expert Predictor # ============================================================================= class ExpertPredictor(nn.Module): """ Predicts SD1.5-flow expert features from (timestep_emb, CLIP_pooled). Training: learns to match real expert features via distillation loss. Inference: runs standalone, no expert model needed. The predictor learns: - What the expert "sees" at each timestep - How text conditioning modulates that view - Trajectory shape priors from the expert's knowledge """ def __init__( self, time_dim: int = 512, clip_dim: int = 768, expert_dim: int = 1280, hidden_dim: int = 512, output_dim: int = 512, dropout: float = 0.1, ): super().__init__() self.expert_dim = expert_dim self.dropout = dropout # Input fusion self.input_proj = nn.Linear(time_dim + clip_dim, hidden_dim) # Predictor core - learns expert behavior self.predictor = nn.Sequential( nn.SiLU(), nn.Linear(hidden_dim, hidden_dim), nn.SiLU(), nn.Dropout(dropout), nn.Linear(hidden_dim, hidden_dim), nn.SiLU(), nn.Linear(hidden_dim, expert_dim), ) # Project predicted expert features to vec dimension self.output_proj = nn.Sequential( nn.LayerNorm(expert_dim), nn.Linear(expert_dim, output_dim), ) # Learnable gate for expert influence self.expert_gate = nn.Parameter(torch.ones(1) * 0.5) self._init_weights() def _init_weights(self): for m in self.modules(): if isinstance(m, nn.Linear): nn.init.xavier_uniform_(m.weight, gain=0.5) if m.bias is not None: nn.init.zeros_(m.bias) def forward( self, time_emb: torch.Tensor, clip_pooled: torch.Tensor, real_expert_features: Optional[torch.Tensor] = None, force_predictor: bool = False, ) -> Dict[str, torch.Tensor]: """ Forward pass. Args: time_emb: [B, time_dim] - timestep embedding from time_in clip_pooled: [B, clip_dim] - pooled CLIP features real_expert_features: [B, expert_dim] - real expert output (training only) force_predictor: if True, use predictor even when real features available Returns: dict with: - 'expert_signal': [B, output_dim] - signal to add to vec - 'expert_pred': [B, expert_dim] - predicted expert features (for loss) - 'expert_used': str - 'real' or 'predicted' """ B = time_emb.shape[0] device = time_emb.device # Fuse inputs combined = torch.cat([time_emb, clip_pooled], dim=-1) hidden = self.input_proj(combined) # Predict expert features expert_pred = self.predictor(hidden) # Decide which features to use use_real = ( real_expert_features is not None and self.training and not force_predictor and torch.rand(1).item() > self.dropout # Sometimes use predictor even in training ) if use_real: expert_features = real_expert_features expert_used = 'real' else: expert_features = expert_pred expert_used = 'predicted' # Project to output dimension with gating gate = torch.sigmoid(self.expert_gate) expert_signal = gate * self.output_proj(expert_features) return { 'expert_signal': expert_signal, 'expert_pred': expert_pred, 'expert_used': expert_used, } def compute_distillation_loss( self, expert_pred: torch.Tensor, real_expert_features: torch.Tensor, ) -> torch.Tensor: """MSE loss between predicted and real expert features.""" return F.mse_loss(expert_pred, real_expert_features) # ============================================================================= # AdaLayerNorm # ============================================================================= class AdaLayerNormZero(nn.Module): """AdaLN-Zero for double-stream blocks (6 params).""" def __init__(self, hidden_size: int): super().__init__() self.silu = nn.SiLU() self.linear = nn.Linear(hidden_size, 6 * hidden_size, bias=True) self.norm = RMSNorm(hidden_size) def forward(self, x: torch.Tensor, emb: torch.Tensor): emb_out = self.linear(self.silu(emb)) shift_msa, scale_msa, gate_msa, shift_mlp, scale_mlp, gate_mlp = emb_out.chunk(6, dim=-1) x = self.norm(x) * (1 + scale_msa.unsqueeze(1)) + shift_msa.unsqueeze(1) return x, gate_msa, shift_mlp, scale_mlp, gate_mlp class AdaLayerNormZeroSingle(nn.Module): """AdaLN-Zero for single-stream blocks (3 params).""" def __init__(self, hidden_size: int): super().__init__() self.silu = nn.SiLU() self.linear = nn.Linear(hidden_size, 3 * hidden_size, bias=True) self.norm = RMSNorm(hidden_size) def forward(self, x: torch.Tensor, emb: torch.Tensor): emb_out = self.linear(self.silu(emb)) shift, scale, gate = emb_out.chunk(3, dim=-1) x = self.norm(x) * (1 + scale.unsqueeze(1)) + shift.unsqueeze(1) return x, gate # ============================================================================= # Attention # ============================================================================= class Attention(nn.Module): """Multi-head attention.""" def __init__(self, hidden_size: int, num_heads: int, head_dim: int, use_bias: bool = False): super().__init__() self.num_heads = num_heads self.head_dim = head_dim self.scale = head_dim ** -0.5 self.qkv = nn.Linear(hidden_size, 3 * num_heads * head_dim, bias=use_bias) self.out_proj = nn.Linear(num_heads * head_dim, hidden_size, bias=use_bias) def forward(self, x: torch.Tensor, rope: Optional[torch.Tensor] = None) -> torch.Tensor: B, N, _ = x.shape qkv = self.qkv(x).reshape(B, N, 3, self.num_heads, self.head_dim) q, k, v = qkv.permute(2, 0, 3, 1, 4) if rope is not None: q = apply_rotary_emb_old(q, rope) k = apply_rotary_emb_old(k, rope) attn = F.scaled_dot_product_attention(q, k, v) out = attn.transpose(1, 2).reshape(B, N, -1) return self.out_proj(out) class JointAttention(nn.Module): """Joint attention for double-stream blocks.""" def __init__(self, hidden_size: int, num_heads: int, head_dim: int, use_bias: bool = False): super().__init__() self.num_heads = num_heads self.head_dim = head_dim self.scale = head_dim ** -0.5 self.txt_qkv = nn.Linear(hidden_size, 3 * num_heads * head_dim, bias=use_bias) self.img_qkv = nn.Linear(hidden_size, 3 * num_heads * head_dim, bias=use_bias) self.txt_out = nn.Linear(num_heads * head_dim, hidden_size, bias=use_bias) self.img_out = nn.Linear(num_heads * head_dim, hidden_size, bias=use_bias) def forward( self, txt: torch.Tensor, img: torch.Tensor, rope: Optional[torch.Tensor] = None, ) -> Tuple[torch.Tensor, torch.Tensor]: B, L, _ = txt.shape _, N, _ = img.shape txt_qkv = self.txt_qkv(txt).reshape(B, L, 3, self.num_heads, self.head_dim) img_qkv = self.img_qkv(img).reshape(B, N, 3, self.num_heads, self.head_dim) txt_q, txt_k, txt_v = txt_qkv.permute(2, 0, 3, 1, 4) img_q, img_k, img_v = img_qkv.permute(2, 0, 3, 1, 4) if rope is not None: img_q = apply_rotary_emb_old(img_q, rope) img_k = apply_rotary_emb_old(img_k, rope) k = torch.cat([txt_k, img_k], dim=2) v = torch.cat([txt_v, img_v], dim=2) txt_out = F.scaled_dot_product_attention(txt_q, k, v) txt_out = txt_out.transpose(1, 2).reshape(B, L, -1) img_out = F.scaled_dot_product_attention(img_q, k, v) img_out = img_out.transpose(1, 2).reshape(B, N, -1) return self.txt_out(txt_out), self.img_out(img_out) # ============================================================================= # MLP # ============================================================================= class MLP(nn.Module): """Feed-forward network with GELU activation.""" def __init__(self, hidden_size: int, mlp_ratio: float = 4.0): super().__init__() mlp_hidden = int(hidden_size * mlp_ratio) self.fc1 = nn.Linear(hidden_size, mlp_hidden, bias=True) self.act = nn.GELU(approximate='tanh') self.fc2 = nn.Linear(mlp_hidden, hidden_size, bias=True) def forward(self, x: torch.Tensor) -> torch.Tensor: return self.fc2(self.act(self.fc1(x))) # ============================================================================= # Transformer Blocks # ============================================================================= class DoubleStreamBlock(nn.Module): """Double-stream transformer block.""" def __init__(self, config: TinyFluxDeepConfig): super().__init__() hidden = config.hidden_size heads = config.num_attention_heads head_dim = config.attention_head_dim self.img_norm1 = AdaLayerNormZero(hidden) self.txt_norm1 = AdaLayerNormZero(hidden) self.attn = JointAttention(hidden, heads, head_dim, use_bias=False) self.img_norm2 = RMSNorm(hidden) self.txt_norm2 = RMSNorm(hidden) self.img_mlp = MLP(hidden, config.mlp_ratio) self.txt_mlp = MLP(hidden, config.mlp_ratio) def forward( self, txt: torch.Tensor, img: torch.Tensor, vec: torch.Tensor, rope: Optional[torch.Tensor] = None, ) -> Tuple[torch.Tensor, torch.Tensor]: img_normed, img_gate_msa, img_shift_mlp, img_scale_mlp, img_gate_mlp = self.img_norm1(img, vec) txt_normed, txt_gate_msa, txt_shift_mlp, txt_scale_mlp, txt_gate_mlp = self.txt_norm1(txt, vec) txt_attn_out, img_attn_out = self.attn(txt_normed, img_normed, rope) txt = txt + txt_gate_msa.unsqueeze(1) * txt_attn_out img = img + img_gate_msa.unsqueeze(1) * img_attn_out txt_mlp_in = self.txt_norm2(txt) * (1 + txt_scale_mlp.unsqueeze(1)) + txt_shift_mlp.unsqueeze(1) img_mlp_in = self.img_norm2(img) * (1 + img_scale_mlp.unsqueeze(1)) + img_shift_mlp.unsqueeze(1) txt = txt + txt_gate_mlp.unsqueeze(1) * self.txt_mlp(txt_mlp_in) img = img + img_gate_mlp.unsqueeze(1) * self.img_mlp(img_mlp_in) return txt, img class SingleStreamBlock(nn.Module): """Single-stream transformer block.""" def __init__(self, config: TinyFluxDeepConfig): super().__init__() hidden = config.hidden_size heads = config.num_attention_heads head_dim = config.attention_head_dim self.norm = AdaLayerNormZeroSingle(hidden) self.attn = Attention(hidden, heads, head_dim, use_bias=False) self.mlp = MLP(hidden, config.mlp_ratio) self.norm2 = RMSNorm(hidden) def forward( self, txt: torch.Tensor, img: torch.Tensor, vec: torch.Tensor, rope: Optional[torch.Tensor] = None, ) -> Tuple[torch.Tensor, torch.Tensor]: L = txt.shape[1] x = torch.cat([txt, img], dim=1) x_normed, gate = self.norm(x, vec) x = x + gate.unsqueeze(1) * self.attn(x_normed, rope) x = x + self.mlp(self.norm2(x)) txt, img = x.split([L, x.shape[1] - L], dim=1) return txt, img # ============================================================================= # Main Model # ============================================================================= class TinyFluxDeep(nn.Module): """ TinyFlux-Deep with Expert Predictor. The expert predictor learns to emulate SD1.5-flow's timestep expertise, allowing the model to benefit from trajectory priors without requiring the expert model at inference time. """ def __init__(self, config: Optional[TinyFluxDeepConfig] = None): super().__init__() self.config = config or TinyFluxDeepConfig() cfg = self.config # Input projections self.img_in = nn.Linear(cfg.in_channels, cfg.hidden_size, bias=True) self.txt_in = nn.Linear(cfg.joint_attention_dim, cfg.hidden_size, bias=True) # Conditioning self.time_in = MLPEmbedder(cfg.hidden_size) self.vector_in = nn.Sequential( nn.SiLU(), nn.Linear(cfg.pooled_projection_dim, cfg.hidden_size, bias=True) ) # Expert predictor (replaces guidance_in) if cfg.use_expert_predictor: self.expert_predictor = ExpertPredictor( time_dim=cfg.hidden_size, clip_dim=cfg.pooled_projection_dim, expert_dim=cfg.expert_dim, hidden_dim=cfg.expert_hidden_dim, output_dim=cfg.hidden_size, dropout=cfg.expert_dropout, ) else: self.expert_predictor = None # Legacy guidance (for backward compat / comparison) if cfg.guidance_embeds: self.guidance_in = MLPEmbedder(cfg.hidden_size) else: self.guidance_in = None # RoPE self.rope = EmbedND(theta=10000.0, axes_dim=cfg.axes_dims_rope) # Transformer blocks self.double_blocks = nn.ModuleList([ DoubleStreamBlock(cfg) for _ in range(cfg.num_double_layers) ]) self.single_blocks = nn.ModuleList([ SingleStreamBlock(cfg) for _ in range(cfg.num_single_layers) ]) # Output self.final_norm = RMSNorm(cfg.hidden_size) self.final_linear = nn.Linear(cfg.hidden_size, cfg.in_channels, bias=True) self._init_weights() def _init_weights(self): def _init(module): if isinstance(module, nn.Linear): nn.init.xavier_uniform_(module.weight) if module.bias is not None: nn.init.zeros_(module.bias) self.apply(_init) nn.init.zeros_(self.final_linear.weight) def forward( self, hidden_states: torch.Tensor, encoder_hidden_states: torch.Tensor, pooled_projections: torch.Tensor, timestep: torch.Tensor, img_ids: torch.Tensor, txt_ids: Optional[torch.Tensor] = None, guidance: Optional[torch.Tensor] = None, expert_features: Optional[torch.Tensor] = None, return_expert_pred: bool = False, ) -> torch.Tensor: """ Forward pass. Args: hidden_states: [B, N, C] - image latents encoder_hidden_states: [B, L, D] - T5 text embeddings pooled_projections: [B, D] - CLIP pooled features timestep: [B] - diffusion timestep img_ids: [N, 3] or [B, N, 3] - image position IDs txt_ids: [L, 3] or [B, L, 3] - text position IDs (optional) guidance: [B] - legacy guidance scale (if guidance_embeds=True) expert_features: [B, 1280] - real expert features (training only) return_expert_pred: if True, return (output, expert_info) tuple Returns: output: [B, N, C] - predicted velocity expert_info: dict (if return_expert_pred=True) """ B = hidden_states.shape[0] L = encoder_hidden_states.shape[1] N = hidden_states.shape[1] # Input projections img = self.img_in(hidden_states) txt = self.txt_in(encoder_hidden_states) # Conditioning: time + pooled text time_emb = self.time_in(timestep) vec = time_emb + self.vector_in(pooled_projections) # Expert predictor (third stream) expert_info = None if self.expert_predictor is not None: expert_out = self.expert_predictor( time_emb=time_emb, clip_pooled=pooled_projections, real_expert_features=expert_features, ) vec = vec + expert_out['expert_signal'] expert_info = expert_out # Legacy guidance (fallback) elif self.guidance_in is not None and guidance is not None: vec = vec + self.guidance_in(guidance) # Handle img_ids shape if img_ids.ndim == 3: img_ids = img_ids[0] img_rope = self.rope(img_ids) # Double-stream blocks for block in self.double_blocks: txt, img = block(txt, img, vec, img_rope) # Build full sequence RoPE for single-stream if txt_ids is None: txt_ids = torch.zeros(L, 3, device=img_ids.device, dtype=img_ids.dtype) elif txt_ids.ndim == 3: txt_ids = txt_ids[0] all_ids = torch.cat([txt_ids, img_ids], dim=0) full_rope = self.rope(all_ids) # Single-stream blocks for block in self.single_blocks: txt, img = block(txt, img, vec, full_rope) # Output img = self.final_norm(img) output = self.final_linear(img) if return_expert_pred: return output, expert_info return output def compute_loss( self, output: torch.Tensor, target: torch.Tensor, expert_pred: Optional[torch.Tensor] = None, real_expert_features: Optional[torch.Tensor] = None, distill_weight: float = 0.1, ) -> Dict[str, torch.Tensor]: """ Compute combined loss. Args: output: model prediction target: flow matching target (data - noise) expert_pred: predicted expert features real_expert_features: real expert features distill_weight: weight for distillation loss Returns: dict with 'total', 'main', 'distill' losses """ # Main flow matching loss main_loss = F.mse_loss(output, target) losses = { 'main': main_loss, 'distill': torch.tensor(0.0, device=output.device), 'total': main_loss, } # Distillation loss if expert_pred is not None and real_expert_features is not None: distill_loss = self.expert_predictor.compute_distillation_loss( expert_pred, real_expert_features ) losses['distill'] = distill_loss losses['total'] = main_loss + distill_weight * distill_loss return losses @staticmethod def create_img_ids(batch_size: int, height: int, width: int, device: torch.device) -> torch.Tensor: """Create image position IDs for RoPE.""" img_ids = torch.zeros(height * width, 3, device=device) for i in range(height): for j in range(width): idx = i * width + j img_ids[idx, 0] = 0 img_ids[idx, 1] = i img_ids[idx, 2] = j return img_ids @staticmethod def create_txt_ids(text_len: int, device: torch.device) -> torch.Tensor: """Create text position IDs.""" txt_ids = torch.zeros(text_len, 3, device=device) txt_ids[:, 0] = torch.arange(text_len, device=device) return txt_ids def count_parameters(self) -> Dict[str, int]: """Count parameters by component.""" counts = {} counts['img_in'] = sum(p.numel() for p in self.img_in.parameters()) counts['txt_in'] = sum(p.numel() for p in self.txt_in.parameters()) counts['time_in'] = sum(p.numel() for p in self.time_in.parameters()) counts['vector_in'] = sum(p.numel() for p in self.vector_in.parameters()) if self.expert_predictor is not None: counts['expert_predictor'] = sum(p.numel() for p in self.expert_predictor.parameters()) if self.guidance_in is not None: counts['guidance_in'] = sum(p.numel() for p in self.guidance_in.parameters()) counts['double_blocks'] = sum(p.numel() for p in self.double_blocks.parameters()) counts['single_blocks'] = sum(p.numel() for p in self.single_blocks.parameters()) counts['final'] = sum(p.numel() for p in self.final_norm.parameters()) + \ sum(p.numel() for p in self.final_linear.parameters()) counts['total'] = sum(p.numel() for p in self.parameters()) return counts # ============================================================================= # Test # ============================================================================= def test_model(): """Test TinyFlux-Deep with Expert Predictor.""" print("=" * 60) print("TinyFlux-Deep + Expert Predictor Test") print("=" * 60) config = TinyFluxDeepConfig( use_expert_predictor=True, expert_dim=1280, expert_hidden_dim=512, guidance_embeds=False, ) model = TinyFluxDeep(config) counts = model.count_parameters() print(f"\nConfig:") print(f" hidden_size: {config.hidden_size}") print(f" num_double_layers: {config.num_double_layers}") print(f" num_single_layers: {config.num_single_layers}") print(f" expert_dim: {config.expert_dim}") print(f" use_expert_predictor: {config.use_expert_predictor}") print(f"\nParameters:") for name, count in counts.items(): print(f" {name}: {count:,}") device = 'cuda' if torch.cuda.is_available() else 'cpu' model = model.to(device) B, H, W = 2, 64, 64 L = 77 hidden_states = torch.randn(B, H * W, config.in_channels, device=device) encoder_hidden_states = torch.randn(B, L, config.joint_attention_dim, device=device) pooled_projections = torch.randn(B, config.pooled_projection_dim, device=device) timestep = torch.rand(B, device=device) img_ids = TinyFluxDeep.create_img_ids(B, H, W, device) txt_ids = TinyFluxDeep.create_txt_ids(L, device) # Simulated expert features expert_features = torch.randn(B, config.expert_dim, device=device) print("\n[Test 1: Training mode with expert features]") model.train() with torch.no_grad(): output, expert_info = model( hidden_states=hidden_states, encoder_hidden_states=encoder_hidden_states, pooled_projections=pooled_projections, timestep=timestep, img_ids=img_ids, txt_ids=txt_ids, expert_features=expert_features, return_expert_pred=True, ) print(f" Output shape: {output.shape}") print(f" Expert used: {expert_info['expert_used']}") print(f" Expert pred shape: {expert_info['expert_pred'].shape}") print("\n[Test 2: Inference mode (no expert)]") model.eval() with torch.no_grad(): output = model( hidden_states=hidden_states, encoder_hidden_states=encoder_hidden_states, pooled_projections=pooled_projections, timestep=timestep, img_ids=img_ids, txt_ids=txt_ids, expert_features=None, # No expert at inference ) print(f" Output shape: {output.shape}") print(f" Output range: [{output.min():.4f}, {output.max():.4f}]") print("\n[Test 3: Loss computation]") target = torch.randn_like(output) model.train() output, expert_info = model( hidden_states=hidden_states, encoder_hidden_states=encoder_hidden_states, pooled_projections=pooled_projections, timestep=timestep, img_ids=img_ids, txt_ids=txt_ids, expert_features=expert_features, return_expert_pred=True, ) losses = model.compute_loss( output=output, target=target, expert_pred=expert_info['expert_pred'], real_expert_features=expert_features, distill_weight=0.1, ) print(f" Main loss: {losses['main']:.4f}") print(f" Distill loss: {losses['distill']:.4f}") print(f" Total loss: {losses['total']:.4f}") print("\n" + "=" * 60) print("✓ All tests passed!") print("=" * 60) if __name__ == "__main__": test_model()